Animal Viruses, Prions, & Viroids PDF

Summary

This document provides an overview of animal viruses, prions, and viroids. It details several aspects of animal virus replication, including attachment, entry, synthesis, assembly, and release. The document also discusses animal virus replication and the various types of viruses, including DNA, RNA, and reverse-transcribing viruses.

Full Transcript

Animal Viruses, Prions, & Viroids
Chapter 11

Scanning electron micrograph of Ebola virus budding from the surface of a Vero cell Notice: This material is subject to the U.S. Copyright Law; furth
Animal and Plant Viruses
▪ Animal and plant viruses solve problems
similar to those faced by bacteriophages:
Host attachment, genome entry
and gene expression, virion
assembly, and virion release
▪ However, eukaryotic cells have a more
complex structure than prokaryotic cells.
Therefore, animal and plant viruses
have greater complexity and
diversity of viral replication cycles
than we see in bacteriophages.
 Animal Virus Replication

▪ Five-step infection cycle
Understanding the infection cycle
of viruses is important from a
medical standpoint

Knowledge of proteins involved in
infection allows researchers to
develop anti-viral medications

© McGraw Hill, LLC
Animal Viruses Show Tissue Tropism

▪ Animal viruses bind specific
receptor proteins on their host
cell.
Receptors determine the
viral tropism, or ability to
infect a particular host,
tissue, cell.
For example, Ebola virus
exhibits broad tropism by
infecting many hosts and
tissues within a host

Speranza E, Connor JH. Host Transcriptional Response to Ebola Virus Infection. Vaccines. 2017; 5(3):30.
https://doi.org/10.3390/vaccines5030030. Licensee MDPI, Basel, Switzerland. CC BY 4.0
 Animal Virus Replication

Five-step infection cycle
1. Attachment
Viral spikes bind to receptors on host’s cell surface
Usually glycoproteins on cytoplasmic membrane
Often more than one required (ex: HIV binds to two)
Function of host receptors unrelated to viral infection

Specific host cell receptors required for attachment; limits tissue and host
range of virus
Some have narrow host range – influenza virus infects cells lining the respiratory
tracts of humans
Some have broad host range - rabies virus infects nerve cells of many mammal
species
Modification of image from Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
 Liu, J., Li, Y., Liu, Q. et
al. SARS-CoV-2 cell tropism
and multiorgan
infection. Cell Discov 7, 17
(2021).
https://doi.org/10.1038/s41
421-021-00249-2 CC BY

SARS-CoV-2 tropism is correlated with ACE 2/TMPRSS2 distribution in the body
Animal Virus Replication

Five-step infection cycle
2-3. Entry and uncoating
– fusion vs endocytosis
Only enveloped viruses
enter via fusion
Lipid envelope of
enveloped virus allows
fusion
Fuses with cytoplasmic
membrane
Leaving free nucleocapsid
in cytoplasm

© McGraw Hill, LLC
Animal Virus Replication
Five-step infection cycle
2-3. Entry and uncoating:
Some enveloped and all non-
enveloped virions enter by
triggering endocytosis
Take advantage of receptor-
mediated endocytosis
Binds to receptors that
normally trigger this process
If enveloped, viral envelope
fuses with endosome
membrane, leaving free
nucleocapsid
If non-enveloped, nucleic acid
is released in cytoplasm once
in endosome

© McGraw Hill, LLC
Animal Virus Replication
Influenza Virus

Five-step infection cycle
Entry and uncoating: fusion or
endocytosis
In both fusion and endocytosis, entire virion
enters cell (unlike phages)
Uncoating then occurs – separation of nucleic
acid from protein coat
uncoating occurs through virus-specific, complex
processes triggered by virus-host cell interactions
Ex: Poliovirus and rhinovirus – attachment to surface
receptors induces conformational changes in capsid,
inducing uncoating
EX: Influenza – low pH of endosome triggers uncoating

Nucleic acid then can enter the nucleus via
nuclear pores to replicate
© McGraw Hill, LLC
Animal Virus Replication

Five-step infection cycle
4. Synthesis (production of new viral particles) requires two
interrelated events
I. Expression of viral genes to produce viral structural and
catalytic proteins
Ex: capsid proteins, enzymes required for replication
II. Synthesis of multiple copies of the genome

Three general replication strategies depending on viral
genome type
– DNA viruses
– RNA viruses
– Reverse-transcribing viruses
Animal Virus Replication

▪ The primary factor that dictates the details of the synthesis stage of an animal virus is the
form of its genome.
▪ DNA viruses
Utilize some or all of the host replication machinery (DNA polymerase)
▪ RNA viruses
Use an RNA-dependent RNA polymerase (replicase) to transcribe viral mRNA
▪ Retroviruses
Use an RNA-dependent DNA polymerase (reverse transcriptase) to copy their genomic
sequence into DNA for insertion in the host chromosome

11
Animal Virus Replication

Five-step infection cycle
Replication of DNA viruses
Usually occurs in host cell’s nucleus
Prefer to use host DNA polymerase
But often encode their own DNA polymerase
– allows replication even if host cell is not
actively replicating its own chromosome
dsDNA replication straightforward (follows
Central Dogma of Molecular Biology)

Illustration of the Replication of a Double-Stranded DNA Viral Genome and production of Viral
mRNA.jpg by Gary E. Kaiser, Ph.D. https://cwoer.ccbcmd.edu/science/microbiology CC BY 4.0
 Animal Virus Replication
Five-step infection cycle
Replication of DNA viruses
ssDNA replication similar except
complement first synthesized ->
dsDNA intermediate
ss(-)DNA viruses: (-) strand for
transcribing mRNA; (+) strand
for genome replication
ss(+)DNA viruses: (-) strand
used for both; still needs dsDNA
intermediated

Illustration of the Replication of a Single-Stranded DNA Viral Genome and production of Viral
mRNA.jpg by Gary E. Kaiser, Ph.D. https://cwoer.ccbcmd.edu/science/microbiology CC BY 4.0
Animal Virus Replication
Five-step infection cycle
Replication of RNA viruses
Majority are single-stranded;
replicate in cytoplasm
Uses virally encoded RNA
polymerase – Replicase ->
RNA-dependent RNA Poly
Unique: normal RNA polymerase
only can synthesize from DNA ->
DNA-dependent RNA Poly
Used to replicate genome and
make mRNA for protein synthesis lustration of the Replication of a Single-Stranded Plus RNA Viral Genome and production of Viral
mRNA.jpg by Gary E. Kaiser, Ph.D. https://cwoer.ccbcmd.edu/science/microbiology CC BY 4.0
Animal Virus Replication

Five-step infection cycle
Replication of RNA viruses
ss(+)RNA functions as mRNA and immediately binds
to host ribosomes
First: Replicase translated from mRNA using host ribosome
Then: Replicase replicates the viral genome
The replication cycle of human picornaviruses (common
cold) is representative of (+) sense single-stranded RNA
viruses.

© McGraw Hill, LLC
ACE2 & TMPRSS2 receptors

Majumder, J., Minko, T.
Recent Developments on
Therapeutic and Diagnostic
Approaches for COVID-
19. AAPS J 23, 14 (2021).
https://doi.org/10.1208/s12
248-020-00532-2 CCBY 4.0
 Animal Virus Replication

Five-step infection cycle
Replication of RNA viruses
ss(–)RNA (complement of mRNA)
Carries replicase in nucleocapsid to
synthesize (+) strand
Host cell does not have a polymerase to
transcribe ss- RNA to mRNA

illustration of the Replication of a Single-Stranded Minus RNA Viral Genome and production of Viral
mRNA.jpg by Gary E. Kaiser, Ph.D. https://cwoer.ccbcmd.edu/science/microbiology CC BY 4.0
Influenza virus Replicase (RdRp)
 Animal Virus Replication

Five-step infection cycle
Replication of RNA viruses
dsRNA viruses also carry
replicase in nucleocapsid

illustration of the Replication of a Double-Stranded RNA Viral Genome and production of Viral
mRNA.jpg by Gary E. Kaiser, Ph.D. https://cwoer.ccbcmd.edu/science/microbiology CC BY 4.0
 Animal Virus Replication
Five-step infection cycle
Replication of RNA viruses
RNA viruses have high mutation rate because…
Replicase lacks proofreading and generates mutations
during replication
Mutations may be “lethal” OR lead to genetic variation in
surface proteins (which are recognized by the host’s immune
system)
The latter is called antigenic drift
Ex: New variants of viruses over time

Segmented RNA viruses have genes that are encoded by
2 or more nucleic acid strands
Antigenic shift can occur if host cell is infected by 2 or
more segmented viruses at the same time. New viral
particles can be packaged with RNA segments from both
Modification of images from Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
The Genome of Influenza A

Modification of images from Parker et al. 2022
OpenStax Microbiology CC BY 4.0.

By Ahmed Mostafa, Elsayed M. Abdelwhab, Thomas C. Mettenleiter, and Stephan Pleschka - mdpi.com/1999-4915/10/9/497/htm, CC BY 4.0,
https://commons.wikimedia.org/w/index.php?curid=92987475
Influenza Receptors in Different Hosts

Human influenza viruses (blue) typically
bind to α2,6-linked receptors, while avian
influenza viruses (red) often bind to α2,3-
linked receptors.

Avian influenza viruses typically cannot
readily infect humans.

Swine can act as a "mixing vessel" to
facilitate the transmission of influenza
viruses between avian and human
populations due to their ability to express
both types of receptors.

Kerstetter LJ, Buckley S, Bliss CM and Coughlan L (2021) Adenoviral Vectors as Vaccines for Emerging Avian Influenza Viruses. Front. Immunol. 11:607333. doi: 10.3389/fimmu.2020.607333 CC BY
 Reassortment between Human, Avian, and Swine Strains
If two different strains of influenza virus infect
a host simultaneously, their segments can
reassort to generate a novel hybrid strain –
antigenic shift.
Because influenza genomes are capable of
reassortment, they can rapidly generate a new
strain that our immune system fails to
recognize.
For example, the pandemic H1N1 strain of 2009
was due to a quadruple reassortment of these
strains
The influenza viruses also continually acquire
small mutations that can lead to new
phenotypes with respect to drug resistance
and host range –antigenic drift.
Influenza is a major global public health
challenge.

© McGraw Hill, LLC
Proofreading exonucleases in larger RNA viruses such as SARS-CoV (1 & 2).

Smith EC, Denison MR (2013) Coronaviruses as DNA
Wannabes: A New Model for the Regulation of RNA Virus
Replication Fidelity. PLoS Pathog 9(12): e1003760.
https://doi.org/10.1371/journal.ppat.1003760 CC BY

“The discovery of 3′-to-5′ exoribonuclease (ExoN) activity within CoV nonstructural
protein 14 (nsp14-ExoN), which is critical for CoV high-fidelity replication, has
challenged the long-held paradigm that RNA viruses cannot proofread and raises the
possibility of an entirely new model for how RNA viruses regulate replication fidelity.”
 Animal Virus Replication
Five-step infection cycle
Replication of reverse-transcribing viruses

aka Retroviruses, have ss (+) RNA
genome (ex: HIV)
Lack replicase gene, but carries reverse
transcriptase in virion: makes ssDNA
from RNA (RNA-dep DNA-poly) Integrates
into host cell
Complementary strand synthesized by chromosome
host cell DNA polymerase (provirus)

dsDNA integrates into host cell
chromosome via integrase and forms
provirus
Can direct productive infection or
remain latent
Illustration of the Replication of a Single-Stranded Plus RNA Viral Genome and Production of Viral mRNA by way of
Cannot be eliminated from the host Reverse Transcriptase.jpg by Gary E. Kaiser, Ph.D. https://cwoer.ccbcmd.edu/science/microbiology CC BY 4.0

cell
Animal Virus Replication

▪ The replication cycle of
human immunodeficiency
virus (HIV) is representative
of retroviruses.
▪ HIV is an RNA virus that uses
reverse transcriptase to copy
its RNA genome into double-
stranded DNA.
▪ HIV causes the syndrome
known as AIDS.

© McGraw Hill, LLC
HIV-1 Structure

© McGraw Hill, LLC
HIV Attachment and Host Cell Entry
▪ HIV binds the CD4 receptor of T
lymphocytes together with the
chemokine coreceptor CCR5.
This triggers fusion of the viral
envelope and host membrane,
and the HIV core enters the
cytoplasm.
▪ HIV capsid then dissolves and
releases its contents.

© McGraw Hill, LLC
CCR5 and
CXCR4

NIH Public Domain https://hivinfo.nih.gov/understanding-hiv/infographics/hiv-life-cycle
Integrase

immature HIV HIV RNA
polyproteins

Breaks up
polyproteins into
integrase and
reverse
transcriptase

NIH Public Domain https://hivinfo.nih.gov/understanding-hiv/infographics/hiv-life-cycle
Some research
suggests that in
certain cell types
or under specific
conditions HIV can
enter via
endocytosis

© McGraw Hill, LLC
Animal Virus Replication

Five-step infection cycle
Assembly
Protein capsid forms; genome, enzymes packaged
Occurs spontaneously, but in a step-wise manner
Non-enveloped viruses are completely assembled in the
cytoplasm
Enveloped viruses are completed as they are released
from the cell via budding
 Animal Virus Replication
Five-step infection cycle
5. Release
Most enveloped viruses via budding
Viral protein spikes insert into host cell membrane; matrix proteins accumulates; nucleocapsids extruded
(buds)
Some obtain envelope from organelles (ER) and then transported out of cell via a vesicle - exocytosis
Non-enveloped viruses released when host cell dies – many trigger apoptosis (programmed cell death)

Image cap tured at th e N IAID Integrated Res earch Facili ty (IRF) in Fort Det rick, © McGraw Hi ll, LLC
Maryland. Credit : NIAID (CC BY 2.0)
Structure of Influenza A

34
Influenza Virus Life Cycle

Virion contains eight segments of RNA, each enclosed in
a separate nucleocapsid.

Enters host by receptor-mediated endocytosis.

The low pH of the endosome causes conformational
change.

Facilitates contact with the endosome
membrane, allowing fusion of endosome
membrane and viral envelope to occur.

Influenza components shuttle between the nucleus and
cytoplasm using nuclear localization signals.
Influenza Virus
Is a segmented ss(-)RNA enveloped virus
1. Hemagglutinin (spike) attaches to sialic acid (host
receptor)
2. Induces endocytosis
3. Viral envelope fuses with endosome, releasing
nucleocapsid
4. Capsid uncoats and segmented ssRNA (-) is
released, enters nucleus via pore and host
transport machinery
5. Replicase makes ssRNA (+)
6. ssRNA (+) enters nucleus and is replicated via
replicase and mRNA made
7. Mature mRNA leave nucleus and enter
cytoplasm for translation
8. Viral proteins assemble around membrane and
bud off
9. Neuraminidase (enzyme) on surface prevents
attachment to same cell by cleaving sialic acid
Influenza Virus
Is a segmented ss(-)RNA enveloped virus
1. Hemagglutinin (spike) attaches to sialic acid (host
receptor)
2. Induces endocytosis
3. Viral envelope fuses with endosome, releasing
nucleocapsid
4. Capsid uncoats and segmented ssRNA (-) is
released, enters nucleus via pore and host
transport machinery
5. Replicase makes ssRNA (+)
6. ssRNA (+) enters nucleus and is replicated via
replicase and mRNA made
7. Mature mRNA leave nucleus and enter
cytoplasm for translation
8. Viral proteins assemble around membrane and
bud off
9. Neuraminidase (enzyme) on surface prevents
attachment to same cell by cleaving sialic acid
 Why can’t they cram all the strains of
influenza into a single dose?
Vaccinating people against a disease they're
never going to get is a risky proposition:
We don't know how the body would respond
to a barrage of flu vaccinations.
The patient might also develop a strong
immune response to an insignificant strain,
while skimping on antibodies for a more
prevalent one.

National Institute of Allergy and Infectious Diseases Public Domain
Animal Host Defenses
▪ Since viruses are ubiquitous, a wide range of defense mechanisms have
evolved in animals and plants.
▪ Genetic resistance
– Hosts continually experience mutations – alter receptor proteins

▪ Immune system
– “Innate immunity”— interferons
– “Adaptive immunity”— antibodies

▪ RNA interference (RNAi)
– Alters gene expression and degrades viral RNA
Antiviral Drugs

Drug development has been slow because it is difficult to specifically
target viral replication

→ Viruses use the metabolic machinery of their hosts, which
limits many of the potential points of attack.

Current drugs inhibit virus-specific enzymes and life cycle processes
Mechanisms of Action of Antiviral Medications
Mechanisms of Action of Antiviral Medications
Prevent Viral Entry
New group of chemicals
prevent viral entry into
host cell
Maraviroc blocks HIV
attachment by binding
HIV spike for CCR5

Enfuvirtide binds to HIV
spike that promotes
fusion of viral envelope
with cell membrane

NIH Public Domain https://hivinfo.nih.gov/understanding-hiv/infographics/hiv-life-cycle
 Mechanisms of Action of Antiviral Medications

Interfere with Viral Uncoating
Nucleic acid must separate from
protein coat
Amantadine
Block influenza A viruses from
uncoating by blocking M2-protein
function
Ion channel allows ions to enter
nucleocapsid that aid in fusion
and uncoating
 Mechanisms of Action of Antiviral Medications
Interfere with Nucleic Acid Synthesis
Most antiviral agents work by inhibiting
viral DNA synthesis.
These drugs chemically resemble normal
DNA nucleosides, but they lack the 3' OH
group needed for chain elongation during
DNA synthesis.
DNA chain-terminating analogs are
selectively toxic because viral polymerases
are more prone to incorporate nucleotide
analogs into their nucleic acid than are the
more selective host cell polymerases.
Acyclovir is an analog of thymine-> ceases
DNA replication of HSV (makes its own viral
DNA polymerase)
These drugs do not work on RNA viruses
like influenza.
Mechanisms of Action of Antiviral Medications
Nucleic Acid Synthesis
Replicase Inhibitors
Inhibits replicase
Can bind to cellular polymerase = bad side effects.

Reverse Transcriptase Inhibitors
Inhibits reverse transcriptase
Often used with nucleoside analogs to treat HIV infections
 Mechanisms of Action of Antiviral Medications
Prevent Genome Integration
Raltegravir Inhibits HIV-encoded enzyme
integrase

Prevent Assembly and Release of Viral
Particles
Protease Inhibitors are virus specific
In HIV, prevents cleavage of polyproteins
During replication of HIV, integrase and
reverse transcriptase translated as a
polyprotein that must be cleaved by a
protease.

NIH Public Domain https://hivinfo.nih.gov/understanding-hiv/infographics/hiv-life-cycle
Mechanisms of Action of Antiviral Medications
Prevent Assembly and Release of Viral Particles
Neuraminidase Inhibitors - Tamiflu
Binds to and prevents function of neuraminidase
(releases influenza from budding cell)
Cultivating and Quantitating Animal Viruses
▪ To study, viruses must be grown in appropriate host
Historically, done by inoculating live animals
Cell culture or tissue culture now used
Animal cells grown in liquid medium
▪ Quantitating Animal Viruses
Plaque assays using monolayer of tissue culture cells
Direct counts via Electron microscope
Other Infectious Agents: Viroids and Prions
Viroids are small single-stranded RNA molecules
246–375 nucleotides
Forms closed ring
Discovered in 1971 (potato tuber spindle disease)
Thus far, only found in plants; enter through wound sites
Many questions remain:
How do they replicate?
- Replicated by host RNA
polymerases, but how?
How do they cause disease?
How did they originate?
Do they have counterparts
in animals?
Pamela Roberts,
University of Florida
Institute of Food
and Agricultural
Sciences, USDA ARS)
 Other Infectious Agents: Viroids and Prions

Prions are proteinaceous infectious agents
Composed solely of protein; no nucleic acids
Linked to slow, fatal human diseases; animal
diseases
Mad cow disease – cattle
Chronic wasting disease – deer and elk
Creutzfeldt-Jakob disease – Humans
Variant Creutzfeldt-Jakob disease - Humans (consuming MCD beef)
Usually, transmissible only within species
Mad Cow Disease is an exception, ~170 people
died in England by eating infected tissue
The risk of CWD transmission to humans is
unknown
Other Infectious Agents: Viroids and Prions

Prions
Once infected, prion proteins accumulate in
neural cells
Neurons die
Tissues develop holes (spongiform lesions)
Brain function deteriorates
Characteristic appearance
gives rise to general term for
all prion diseases: transmissible
spongiform encephalopathies
“Figure 6.26 Creutzfeldt-Jakob disease (CJD) is a fatal disease that causes degeneration of neural tissue. (a) These brain scans
compare a normal brain to one with CJD. (b) Compared to a normal brain, the brain tissue of a CJD patient is full of sponge -like
lesions, which result from abnormal formations of prion protein. (credit a (right): modification of work by Dr. Laughlin Dawes;
credit b (top): modification of work by Suzanne Wakim; credit b (bottom): modification of work by Centers for Disease Control
and Prevention)”
Modification of images from Parker et al. 2022 OpenStax Microbiology CC BY 4.0.
Other Infectious Agents: Viroids and Prions
Prions – how do they accumulate in tissue?
Host cells normally produce
cellular/endogenous prion form
PrPC (prion protein, cellular)
Proteases can readily destroy
Infectious prion proteins
PrPSC (prion protein, scrapie)
Hypothesized that PrPSC induces PrPC
misfolding to PrPSC
Resistant to proteases; become insoluble,
aggregate
PrPsc prions in brain tissue can be the result
of a spontaneous mutation in the PrPc
protein gene, or it may originate from PrPsc
prion consumed in food
Modification of images from Parker et al. 2022 OpenStax Microbiology CC BY 4.0.